Demographic Impact of Life Extension Dr. Leonid A. Gavrilov, Ph.D. Dr. Natalia S. Gavrilova, Ph.D. Center on Aging NORC and The University of Chicago Chicago, USA
Rationale A common objection against starting a large-scale biomedical war on aging is the fear of catastrophic population consequences (overpopulation)
Rationale (continued) This fear is only exacerbated by the fact that no detailed demographic projections for radical life extension scenario were conducted so far. What would happen with population numbers if aging-related deaths are significantly postponed or even eliminated? Is it possible to have a sustainable population dynamics in a future hypothetical non-aging society?
The Purpose of this Study This study explores different demographic scenarios and population projections, in order to clarify what could be the demographic consequences of a successful biomedical war on aging.
"Worst" Case Scenario: Immortality Consider the "worst" case scenario (for overpopulation) -- physical immortality (no deaths at all) What would happen with population numbers, then? A common sense and intuition says that there should be a demographic catastrophe, if immortal people continue to reproduce. But what would the science (mathematics) say ?
The case of immortal population Suppose that parents produce less than two children on average, so that each next generation is smaller: Generation (n+1) Generation n Then even if everybody is immortal, the final size of the population will not be infinite, but just larger than the initial population. = r < 1 1/(1 - r) 6
The case of immortal population For example one-child practice (r = 0.5) will only double the total immortal population: Proof: Infinite geometric series converge if the absolute value of the common ratio ( r ) is less than one: 1 + r + r2 + r3 + … + rn + … = 1/(1-r) 1/(1 - r) = 1/0.5 = 2 7
Lesson to be Learned Fears of overpopulation based on lay common sense and uneducated intuition could be exaggerated. Immortality, the joy of parenting, and sustainable population size, are not mutually exclusive. This is because a population of immortal reproducing organisms will grow indefinitely in time, but not necessarily indefinitely in size (asymptotic growth is possible).
Method of population projection Cohort-component method of population projection (standard demographic approach) Age-specific fertility is assumed to remain unchanged over time, to study mortality effects only No migration assumed, because of the focus on natural increase or decline of the population New population projection software is developed using Microsoft Excel macros
Study population: Sweden 2005
Mortality in the study population
Population projection without life extension interventions Start of population decline after 2025 12
Changes in population pyramid 100 years later 13
Why Life-Extension is a Part of the Solution, rather than a Problem Many developed countries (like the studied Sweden) face dramatic decline in native-born population in the future (see earlier graphs) , and also risk to lose their cultural identity due to massive immigration. Therefore, extension of healthy lifespan in these countries may in fact prevent, rather than create a demographic catastrophe.
Scenarios of life extension Negligible senescence Negligible senescence for a part of population (10%) Negligible senescence for a part of population (10%) with growing acceptance (1 percent added to negligible senescence group each year) Rejuvenation (Gompertz alpha = -0.0005) Aging slow down (actuarial aging rate decreases by one half) All anti-aging interventions start at age 60 years with 30-year time lag 15
Negligible senescence after age 60 Scenario 1 Negligible senescence after age 60
Radical scenario: No aging after 60
Population projection with negligible senescence scenario 18
Changes in population pyramid 100 years later
Conclusions on radical scenario Even in the case of defeating aging (no aging after 60 years) the natural population growth is relatively small (about 20% increase over 70 years) Moreover, defeating aging helps to prevent natural population decline in developed countries
Scenario 2 Negligible senescence for a part of population (10%) What if only a small fraction of population accepts anti-aging interventions?
Population projection with 10 percent of population experiencing negligible senescence 22
Changes in population pyramid 100 years later 23
Scenario 3: What happens in the case of growing acceptance of anti-aging interventions? Additional one percent of population starts using life extension technologies every year The last remaining five percent of population refuse to apply these technologies in any circumstances
Population projection with growing acceptance scenario 25
Scenario 4: Rejuvenation Scenario Mortality declines after age 60 years until the levels observed at age 10 are reached; mortality remains constant thereafter Negative Gompertz alpha (alpha = -0.0005 per year)
Radical scenario: rejuvenation after 60 According to this scenario, mortality declines with age after age 60 years
Population projection with rejuvenation scenario 28
Changes in population pyramid 100 years later 29
Conclusions on rejuvenation scenario Even in the case of rejuvenation (aging reversal after 60 years) the natural population growth is still small (about 20% increase over 70 years) Moreover, rejuvenation helps to prevent natural population decline in developed countries
What happens when rejuvenation starts at age 40 instead of age 60?
Population projection with rejuvenation at ages 60 and 40 32
Scenario 5 More modest scenario: Aging slow down Gompertz alpha decreases by one half
Modest scenario: slowing down aging after 60
Population projection with aging slow down scenario 35
Changes in population pyramid 100 years later 36
Conclusions A general conclusion of this study is that population changes are surprisingly small and slow in their response to a dramatic life extension. Even in the case of the most radical life extension scenario, population growth could be relatively slow and may not necessarily lead to overpopulation. Therefore, the real concerns should be placed not on the threat of catastrophic population consequences (overpopulation), but rather on such potential obstacles to a success of biomedical war on aging, as scientific, organizational and financial limitations.
Acknowledgments This study was made possible thanks to: generous support from the SENS/Methuselah Foundation
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